DE102012109432A1 - Fuel cell operation with a failed open injector - Google Patents

Abstract

A system and method for controlling hydrogen gas flow to an anode side of a fuel cell stack using a pressure regulator in the event that an injector that normally injects the hydrogen gas into the fuel cell stack is stuck in a failed open position. During normal operation, the control of the injector is determined based on the pressure of the anode subsystem and the position of the pressure regulator based on a supply pressure between the pressure regulator and the injector. If it is determined that the injector is stuck in an open position, the position of the pressure regulator is controlled to the anode pressure rather than to the supply pressure. If the pressure regulator is an electrical pressure regulator, then it is pulsed to mimic normal system operation. Alternatively, another valve such as a shut-off valve may be used to ensure flow pulses.

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

This invention relates generally to a system and method for controlling the flow of an anode gas to a fuel cell stack with respect to an injector that is in a failed stuck open position, and more particularly to a system and method for controlling the flow of an anode gas to a fuel cell stack with respect to an injector that is in a failed stuck open position, the system using a pressure regulator controlled with an anode gas system pressure to control the flow of the anode gas.

2. Discussion of the Related Art

Hydrogen is a very attractive fuel because it is clean and can be used to efficiently produce electricity in a fuel cell. The automotive industry is spending significant resources on the development of hydrogen fuel cell systems as a vehicle power source. Such vehicles would be more efficient and produce fewer emissions than current vehicles using internal combustion engines. Fuel cell vehicles are expected to rapidly gain popularity in the automotive market in the near future.

Proton Exchange Membrane Fuel Cells (PEMFC) are a popular fuel cell for vehicles. A PEMFC generally includes a solid polymer electrolyte proton conductive membrane, such as a perfluorosulfonic acid membrane. The anode and cathode typically include finely divided catalyst particles, usually platinum (Pt) dispersed on carbon particles and mixed with an ionomer. The catalyst mixture is applied to opposite sides of the membrane. The combination of the anode catalyst mixture, the cathode catalyst mixture and the membrane define a membrane electrode assembly (MEA). MEAs are relatively expensive to manufacture and require certain conditions for effective operation.

Typically, multiple fuel cells are combined into a fuel cell stack to generate the desired performance. For example, a fuel cell stack for a vehicle may include two hundred or more stacked fuel cells. The fuel cell stack receives a cathode input gas, typically with an air flow passing through the stack by means of a compressor. Not all of the oxygen is consumed by the stack, and some of the air is discharged as the cathode exhaust, and the cathode exhaust may include water as a stack waste product. The fuel cell stack also receives an anode hydrogen input gas that flows into the anode side of the stack.

A fuel cell stack typically has a series of bipolar plates disposed in the stack between the plurality of MEAs, with the bipolar plates and the MEAs disposed between two end plates. The bipolar plates include an anode side and a cathode side to adjacent fuel cells in the stack. Anode gas flow channels are provided on the anode side of the bipolar plates that allow the anode reaction gas to flow to the respective MEA. Cathode gas flow channels are provided on the cathode side of the bipolar plates that allow the cathode reaction gas to flow to the respective MEA. One end plate includes anode gas flow channels and the other end plate includes cathode gas flow channels. The bipolar plates and end plates are made of a conductive material such as stainless steel or a conductive composite material. The end plates divert the electricity generated by the fuel cells out of the stack. The bipolar plates further include flow channels through which a coolant flows.

Typically, hydrogen gas for a high pressure fuel cell system is stored in a tank system that provides one or more interconnected pressure vessels on the vehicle to provide the hydrogen gas that is necessary for the fuel cell stack. The pressure inside the boiler can be 700 bar or more. In one known embodiment, the pressure vessels include an inner plastic coating that provides a gas-tight seal for the hydrogen gas, and an outer layer of carbon fiber composite that provides the structural integrity of the boiler.

A hydrogen gas storage system typically includes at least one pressure regulator as part of many and different valves, lines and fittings necessary for operation of the hydrogen storage system, the pressure regulator reducing the pressure of the hydrogen gas from the high pressure in the boilers to a constant pressure is suitable for the fuel cell stack. Various pressure regulators including mechanical pressure regulators and electronic pressure regulators are known in the prior art to ensure this function.

Most fuel cell systems use one or more injectors to inject the hydrogen gas at reduced pressure into the anode side of the fuel cell stack. The injectors are typically controlled with a pulse width modulated signal having a particular duty cycle and a frequency that provides the desired mass flow of hydrogen gas for a given stack current density. In a known fuel cell control system, the load cycle and the frequency of the injector are set to the pressure within an anode subsystem.

For example, the pressure regulator may regulate the pressure of the hydrogen gas from a tank pressure of up to 875 MPa down to about 800 kPa to ensure a constant supply pressure to the injector. The injector then provides a pulsed flow to control the stack anode pressure within a range of 100 to 300 kPa. Maintaining the anode pressure ensures the hydrogen flow needed to power the fuel cell system. It is important to note that both the governor and the injector are needed to provide accurate pressure control across the entire range of power transients for vehicle operation. The injector frequency and pulse width are controlled by a feedback from an anode pressure sensor. In addition, high velocity flow may be provided to an ejector which returns the gas flow from the stack outlet to the stack inlet when the injector is open. This pulsed operation in conjunction with the recirculated flow is necessary to ensure permanent and stable system operation.

During the lifetime of a vehicle, the injector is subjected to hundreds of millions of operating cycles. During this time, there is a risk for the injector to remain tightly seated, which may cause an uncontrolled increase in anode pressure. The pressure rise must be detected and eliminated before the destructive pressure of the stack or other system components is reached, which can damage the system and result in the release of hydrogen gas to the environment. An anode pressure sensor is provided downstream of the injector, and if the sensor detects an increase in anode pressure, the system identifies a failed injector in a stuck open position. The opening of the anode valves is not used to eliminate this error, since the valve flow can not match the indirect flow, and moreover, because the hydrogen flow through the valve can lead to unsafe exhaust emission. Consequently, the typical failure strategy was to shut down the system once a maximum anode pressure had been exceeded. However, this has resulted in the driver getting stranded and leading the driver into an unsafe traffic situation, which is of course an undesirable condition, depending on where the vehicle is at that time.

SUMMARY OF THE INVENTION

In accordance with the teachings of the present invention, a system and method for controlling hydrogen gas flow to an anode side of a fuel cell stack with a pressure regulator is disclosed which, in the event that the injector normally injects the hydrogen gas into the fuel cell stack, is in a failed open state Position is engaged. During normal operation, the opening and closing of the injector is determined based on an anode pressure of an anode subsystem, and the position of the pressure regulator is determined based on a supply pressure between the pressure regulator and the injector. If it is determined that the injector is stuck in an open position, then the position of the pressure regulator is controlled to the anode pressure rather than to the supply pressure. If the pressure regulator is an electrical pressure regulator then it is pulsed to mimic one around normal system operation. Alternatively, another valve, such as a shut-off valve, may be used to provide flow pulses.

Further features of the present invention will become apparent from the following description and the appended claims, taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE FIGURES

1 Fig. 10 is a schematic block diagram of a portion of a fuel cell system showing a flow of hydrogen gas from a high pressure tank to a fuel cell stack; and

2 FIG. 10 is a flowchart showing a method of controlling hydrogen gas flow to a fuel cell stack by means of a pressure regulator; FIG.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The following discussion of embodiments of the invention disclosing a system and method for controlling hydrogen gas flow to an anode side of a fuel cell stack using a pressure regulator is merely exemplary in nature and is in no way intended to limit the invention or its applications or uses. For example, the present Invention a particular application for providing hydrogen gas to the fuel cell stack of a vehicle. However, those skilled in the art will readily recognize that the system and method of the invention finds an application for controlling hydrogen gas flow to another system or other applications.

1 is a simplified schematic block diagram of a fuel cell system 10 with a fuel cell stack 12 , The system 10 includes a high pressure tank 14 which may contain hydrogen gas under a pressure of 700 bar upwards. The Tank 14 may be any high pressure tank suitable for the purposes discussed herein, for example, a high pressure vessel, as mentioned above, having an inner gas tight plastic liner and an outer structural composite material. The high pressure tank 14 includes a fuel shut-off valve 20 that in an output line 18 from the tank 14 intended for security purposes. The tank exit pipe 18 is with an anode input line 24 coupled to the hydrogen gas that is in the tank 14 is stored, to the fuel cell stack 12 supplies. A tank pressure sensor 26 is in the lead 24 provided a high pressure from the pressure inside the tank 14 to be able to read when the valve 20 is open for system control purposes.

A pressure regulator 22 is in the entrance line 24 downstream to the pressure sensor 26 provided, which selectively releases a constant pressure of gas from the high pressure of the tank 14 reduces and ensures that a pressure for the fuel cell stack 12 is provided as known to those skilled in the art. The size of the opening in the regulator 22 and the pressure upstream in the anode conduit 24 regulate the flow rate and the amount of gas downstream to the pressure regulator 22 provided. The pressure regulator 22 may be any pressure regulator suitable for the purposes discussed herein. In a non-limiting embodiment, the pressure regulator 22 an electric pressure regulator that works as a proportional valve with an adjustable opening. As is well known to those skilled in the art, the size of the opening in the regulator regulates 22 and the pressure upstream in the anode conduit 24 the flow rate and the amount of gas downstream to the pressure regulator 22 is delivered. A supply pressure regulator 28 measures the pressure in the pipe 24 downstream to the pressure regulator 22 to be able to read a supply pressure. A regulator 34 uses the supply pressure from the pressure sensor 28 to the position of the opening in the pressure regulator 22 to regulate for the target supply pressure. The regulator 34 receives the pressure measurements from the pressure sensors 26 and 28 and the PWM signal, which is the opening and closing of the injector 16 regulates and regulates the position of the pressure regulator 22 so that the pressure remains essentially constant during normal system operation.

The hydrogen gas with the reduced pressure in the input line 24 downstream to the pressure regulator 22 enters the anode side of the fuel cell stack 12 with an injector 16 injected in a pulsed manner. A pressure sensor 30 will be in the lead 24 downstream to the injector 16 provided and provides an anode subsystem pressure. The pressure sensor 30 may be located at any suitable location in the anode subsystem and in other embodiments. The injector 16 is controlled by a PWM signal to accurately measure the amount of hydrogen gas in the fuel cell stack 12 for the respective stack current density, the PWM signal having a defined duty cycle and frequency based on the anode pressure supplied by the pressure sensor 30 is delivered. Although in this non-limiting embodiment, a single injector is shown to transfer the hydrogen gas into the stack 12 It is known to those skilled in the art that a fuel cell system may include a bank of various injectors that inject the hydrogen gas into the stack 12 inject.

An anode circulation line 32 the anode exhaust gas recirculates from the fuel cell stack 12 back to the injector 16 , In this non-limiting embodiment, the injector includes 16 also an ejector 38 making a combination of the injector 16 and the ejector 38 acting as an injector / ejector, wherein the motive force of the hydrogen gas flowing through the injector, the anode exhaust gas in the injector 16 from the line 32 in a known manner, as known to those skilled in the art. A bleed valve 36 is in the recirculation line 32 provided to nitrogen from the anode side of the fuel cell stack 12 in a manner known to those skilled in the art. Although the system 10 An anode circulation used by the ejector 38 other systems may provide an anode flow inversion system or an anode circulation system provided by a rotary circulation pump.

As will be discussed in detail below, the present invention proposes a technique that allows the fuel cell system 10 the operation also in the case when the injector 16 stuck in an open position, sustains. As discussed above, the duty cycle and the frequency of the injector 16 regulated to the anode pressure by the sensor 30 is delivered to provide the desired gas flow. As soon as the injector 16 is detected as stuck in an open position, which is generally determined by an increase in pressure generated by the pressure sensor 30 is detected, controls the controller 34 then the pressure regulator 22 based on the anode pressure coming from the sensor 30 instead of the supply pressure supplied by the sensor 38 is delivered. The pressure regulator 22 As noted, includes a controllable orifice wherein the position of the orifice is set based on the pressure set point.

It is important that the anode pressure be maintained above the cathode operating pressure and below the maximum allowable anode operating pressure. To achieve this, the maximum stacking power and / or maximum power transients should be responsive to the dynamic flow in response to the controller 22 be limited. In addition, the estimated hydrogen gas flow for the operating conditions and the changes in the pressure setpoints are used to provide feedforward control to the controller 22 provide.

As mentioned, a pulsed recirculation flow is needed to ensure stable operation based on the operation of the ejector 38 maintain. Accordingly, the controller 22 needed to provide a pulsed flow to continue working for a given time. This can be achieved by periodically changing anode pressure set point, which changes in response to the controller 22 limited. The pulsed operation is intended to operate the ejector 38 to mimic, where if a gas recirculation pump instead of an ejector 38 is used, the pulse flow may not be needed. In an alternative embodiment it is also possible, instead of the controller 22 a shut-off valve to provide the pulsed flow 20 to use to deliver the pulsed flow. For these embodiments, in which the controller 22 is a mechanical regulator and it is not possible to provide the pulsed flow, then an additional valve would be needed to provide the pulsed flow if it were necessary for system operation. Accordingly, various embodiments within the scope of the invention can provide a fixed flow of hydrogen gas through the pressure regulator 22 Based on the anode pressure, or requiring a pulsed flow of hydrogen, we can get it from the regulator 23 or another valve is required.

An additional consideration for continued stable operation is to still allow the anode to periodically vent anode gas to build up nitrogen in the anode side of the fuel cell stack 12 to prevent. This requires a periodic opening of the vent valve 36 , The estimated valve flow is in the feedforward control of the controller 22 included, which will dynamically minimize the pressure oscillations as soon as the controller 22 opens and closes. During this failure the regulator will turn 34 the injector 16 periodically press to the injector 16 to adjust for a clean work. This actuation can change the current waveform to the injector 16 change, for example, the size, duration and / or include a variety, so that the failed component for all or a portion of the operating range is restored.

2 is a flowchart 40 which controls the operation, as discussed above, for regulating the flow of hydrogen gas by means of the pressure regulator 22 illustrates when it is determined that the injector 16 stuck in an open position. In the box 42 the algorithm determines that the injector 16 stuck in an open position by determining that the anode pressure generated by the pressure sensor 30 is provided has reached a predetermined maximum pressure. The algorithm then directs the control of the anode gas flow to the pressure regulator 22 in the box 44 over in which the position of the pressure regulator 22 is controlled to the target set point of the anode pressure instead of using the supply pressure supplied by the pressure sensor 28 is delivered. In the box 46 the algorithm limits the performance of the system 10 along with the maximum power and / or power transients, as discussed above. This allows the pressure regulator 22 to effectively control the anode gas flow based on the anode supply pressure. In the box 48 the controller operates on the anode pressure set point and is pulsed in response to the operation of the ejector 38 to ensure. In the box 50 the controller does 34 periodically pressing the injector 16 by providing more power to the injector 16 which is normally used to release it. If the injector 16 is solved again, the system returns 10 return to normal operation, with the injector 16 is regulated to the anode pressure. Operation for using the pressure regulator 22 to control the hydrogen gas flow is continued until the system is shut down or the injector 16 in the box 52 is solved.

As will be well understood by those skilled in the art, various or some of the steps and methods discussed herein to describe the invention may be performed by a computer, processor, or other electronic computing device that manipulates and / or manipulates data using electrical phenomena transformed. These computers and electrical devices may include various volatile and / or nonvolatile memories including a fixed computer readable medium having an executable program thereon containing various codes or executable instructions executed by the computer or processor, the memory and / or the computer readable medium may include all forms and types of memory and other computer readable media.

The foregoing discussion shows and describes purely exemplary embodiments of the present invention. One skilled in the art will readily recognize from the discussion of the attached figures and claims that numerous changes, modifications and variations can be made therein without departing from the spirit and scope of the invention as defined by the following claims.

Claims (10)

A method of controlling a flow of hydrogen gas from a hydrogen gas source to an anode side of a fuel cell stack, the method comprising: Reducing the pressure of hydrogen gas from the hydrogen gas source using a pressure regulator based on a supply pressure provided by a supply pressure sensor disposed downstream of the pressure regulator; Injecting the hydrogen gas from the pressure regulator into the anode side of the fuel cell stack using an injector based on an anode pressure provided by an anode pressure sensor positioned downstream of the injector, the supply pressure sensor disposed upstream of the injector; - determining that the injector is stuck in an open position; Controlling the flow of hydrogen gas to the anode side of the fuel cell stack using the pressure regulator based on the anode pressure instead of the supply pressure if the injector is stuck in an open position. The method of claim 1, wherein controlling the flow of hydrogen gas includes providing a pulsed flow of hydrogen gas. The method of claim 2, wherein the pressure regulator is an electrical pressure regulator and wherein the electrical pressure regulator provides the pulsed flow. The method of claim 2, wherein controlling the flow of hydrogen gas to provide a pulsed flow of hydrogen comprises using a shut-off valve located upstream of the pressure regulator to provide the pulsed flow of hydrogen gas. The method of claim 4, wherein the pressure regulator is a mechanical pressure regulator. The method of claim 1, further comprising periodically attempting to disengage the injector if the injector has been determined to be stuck in an open position. The method of claim 6, wherein periodically attempting to release the injector comprises applying an increased flow of current to the injector. The method of claim 1, further comprising reducing the maximum power of the fuel cell stack and reducing the power and transient rate of the fuel cell stack when the pressure regulator regulates the flow of hydrogen gas to the anode side of the fuel cell stack. The method of claim 1, wherein controlling the flow of hydrogen gas using the pressure regulator includes taking into account the estimated flow through a vent valve. A system for controlling a flow of hydrogen gas to an anode side of a fuel cell stack, the system comprising: A hydrogen gas source providing a source of hydrogen gas; A pressure regulator that receives the hydrogen gas from the hydrogen gas source and regulates the flow of hydrogen gas to reduce the pressure of the hydrogen gas based on a predetermined supply pressure; A supply pressure sensor located downstream of the pressure regulator and providing a measurement of the supply pressure; An injector disposed downstream of the supply pressure regulator and injecting the hydrogen gas from the pressure regulator into the anode side of the fuel cell stack, this injector having a duty cycle to regulate the flow of the anode gas based on an anode pressure; An anode pressure sensor disposed downstream of the injector and providing a pressure measurement of the anode pressure; and A regulator configured to determine whether the injector is stuck in an open position, to control the pressure regulator based on the anode pressure, to regulate the flow of hydrogen gas to the anode side, due to the anode pressure exceeding a maximum anode pressure of the fuel cell stack if the injector is stuck in an open position.

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